INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : I. Antagonistic Effect of Progesterone on Estrogen-Induced Proliferation and Differentiation of Tubular Gland Cells

Daily administration of estrogen to immature female chicks results in marked oviduct growth and appearance of characteristic tubular gland cells which contain lysozyme. Although a rapid increase in total DNA and RNA content begins within 24 hr, cell specific protein, lysozyme, is first detectable after 3 days of estrogen. Progesterone administered concomitantly with estrogen antagonizes the estrogen-induced tissue growth as well as appearance of tubular gland cells and their specific products, lysozyme and ovalbumin. When the initiation of progesterone administration is delayed for progressively longer periods (days) during estrogen treatment, proportionally greater growth occurs with more lysozyme and tubular gland cells after 5 days of total treatment. Progesterone does not inhibit the estrogen-stimulated increase in uptake of α-aminoisobutyric acid and water by oviduct occurring within 24 hr or the estrogen-induced increase in total lipid, phospholipid, and phosphoprotein content of serum. The above results of progesterone antagonism can best be explained by the hypothesis that progesterone inhibits the initial proliferation of cells which become tubular gland cells but does not antagonize the subsequent cytodifferentiation leading to the synthesis of lysozyme and ovalbumin once such cell proliferation has occurred.     

Commitment of chick oviduct tubular gland cells to produce ovalbumin mRNA during hormonal withdrawal and restimulation

Acute withdrawal of estrogen from chicks leads to a precipitous decline in egg white protein synthesis and egg white mRNAs in the oviduct. In this paper we explore the biochemical basis of this phenomenon as well as the capacity of the "withdrawn" tubular gland cells to be restimulated with steroid hormones. During withdrawal, the decline in ovalbumin mRNA was closely correlated with the decline in nuclear estrogen receptors. Within 2-3 d of estrogen removal a withdrawn state was established and then maintained, as defined by a 1,000-fold-lower level of ovalbumin mRNA and a 20-fold-lower level of nuclear estrogen receptors, relative to the estrogen-stimulated state. The number of active forms I and II RNA polymerases declined by 50% during this time. Histological examination of oviduct sections and cell suspensions, combined with measurements of DNA content, revealed that tubular gland cells persisted as a constant proportion of the cell population for 3 d after estrogen removal. Despite a 1,000-fold decrease in the content of ovalbumin mRNA, the ovalbumin gene remained preferentially sensitive to digestion by DNase I. When 3-d-withdrawn oviducts were restimulated with either estrogen or progesterone, in situ hybridization revealed that greater than or equal to 98% of the tubular gland cells contained ovalbumin mRNA. Induction by a suboptimal concentration of estrogen was correlated with a lower concentration of ovalbumin mRNA in all cells rather than fewer responsive cells.     

INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : III. Tubular Gland Cell Cytodifferentiation

Administration of estrogen (E) to immature chicks triggers the cytodifferentiation of tubular gland cells in the magnum portion of the oviduct epithelium; these cells synthesize the major egg-white protein, ovalbumin. Electron microscopy and immunoprecipitation of ovalbumin from oviduct explants labeled with radioactive amino acids in tissue culture were used to follow and measure the degree of tubular gland cell cytodifferentiation. Ovalbumin is undetectable in the unstimulated chick oviduct and in oviducts of chicks treated with progesterone (P) for up to 5 days. Ovalbumin synthesis is first detected 24 hr after E administration, and by 5 days it accounts for 35% of the soluble protein being synthesized. Tubular gland cells begin to synthesize ovalbumin before gland formation which commences after 36 hr of E treatment. When E + P are administered together there is initially a synergistic effect on ovalbumin synthesis, however, after 2 days ovalbumin synthesis slows and by 5 days there is only 1/20th as much ovalbumin per magnum as in the E-treated controls. Whereas the magnum wet weight doubles about every 21 hr with E alone, growth stops after 3 days of E + P treatment. Histological and ultrastructural observations show that the partially differentiated tubular gland cells resulting from E + P treatment never invade the stroma and form definitive glands, as they would with E alone. Instead, these cells appear to transform into other cell types—some with cilia and some with unusual flocculent granules. We present a model of tubular gland cell cytodifferentiation and suggest that a distinct protodifferentiated stage exists. P appears to interfere with the normal transition from the protodifferentiated state to the mature tubular gland cell.     

In situ hybridization of ovalbumin mRNA in the chick oviduct reveals target cell specificity for estrogen and progesterone

An in situ hybridization method using paraffin-embedded sections was used to characterize the chicken oviduct cells synthesizing ovalbumin mRNA due to the action of estrogen and progesterne. The cytodifferentiation of the oviduct cells was induced by 17β-estradiol administration to newly hatched female chicks. To avoid possible effect of estrogen on the action of progesterone the chicks were withdrawn from the estrogen by six days withdrawal period without hormone treatment. Ovalbumin mRNA was not synthesized after a period of estrogen withdrawal. Administration of estrogen induced ovalbumin mRNA in the tubular gland cells. Administration of progesterone induced the expression of ovalbumin mRNA in the surface epithelial cells. It was also found that progesterone induced mucus producing goblet cells in the surface epithelium. Estrogen did not have an effect on the mucus production, which suggests that progesterone could induce the terminal differentiation of the goblet cells. We conclude that the expression of ovalbumin in the surface epithelial cells and in the tubular gland cells is specific for progesterone and estrogen, respectively.     

Steroid hormones induce cell proliferation and specific protein synthesis in primary chick oviduct cultures

A rapid method to obtain large amounts of tubular gland cells from chick oviduct was developed. Combined collagenase and trypsin treatment allowed within 1.5 h complete dissociation of the magnum portion of the oviduct. By differential attachment of cells, fibroblasts were separated from tubular gland- and ciliated cells. Tubular gland cells attached within 18 h to plastic Petri dishes, had large secretory granules and grew very actively. The responsiveness of cells to hormones and/or antihormone was tested by measurement of cell proliferation and specific protein synthesis. After 7 days of culture in the presence of estradiol (50 nM) or progesterone (100 nM), cell growth was increased by approximately 50 and 35% respectively. Tamoxifen (100 nM) inhibited the estradiol induced growth stimulation, but had also negative effects of its own. The anti-progesterone (in mammals) RU 486, inactive per se, did not antagonize progesterone induced growth. Ovalbumin- and conalbumin synthesis after 4-5 days of cultures under different hormonal conditions was assessed after immunoprecipitation of newly synthesized [35S]methionine labelled proteins. In the presence of estradiol (50 and 100 nM), progesterone (50 nM), and both estradiol and progesterone together (50 nM of each), ovalbumin and conalbumin synthesis was increased, when compared to control cultures without hormones, or to oviduct fibroblasts. Hormonal stimulation of ovalbumin synthesis was also shown in cell supernatant and culture medium after gel electrophoresis.     

Estrogen Receptor Is Not Primarily Responsible for Altered Responsiveness of Ovalbumin mRNA Induction in the Oviduct From Genetically Selected High- and Low-Albumen Chicken Lines

The role of estrogen receptor on ovalbumin mRNA induction by steroid hormones was investigated in primary cultures of oviduct cells from estrogen-stimulated immature chicks of genetically selected high- and low-albumen egg laying lines (H- and L-lines). In experiment 1,the extent of ovalbumin mRNA induction and changes in estrogen and progesterone receptors were compared between the oviduct cells from H- and L-lines with or without steroid hormones in the culture medium. In experiment 2, the effect of estrogen receptor gene transfection on the induction of ovalbumin mRNA was studied in the oviduct cells from the L-line chicks. The results showed a close correlation of the changes in ovalbumin mRNA with the numbers of nuclear and total estrogen receptors in the oviduct cells but not with the numbers of nuclear and total progesterone receptors. Estrogen receptor gene transfection induced ovalbumin mRNA to a moderate extent in the absence of the steroid hormones. To our surprise, however, estrogen receptor gene transfection apparently suppressed the ovalbumin mRNA responsiveness to estrogen to a considerable extent. It was concluded, therefore, that the extent of estrogen receptor expression might not be primarily responsible for the differences in responsiveness to steroid hormones of oviduct cells from genetically selected H- and L-line chickens.     

Modification of cell evagination and cell differentiation in quail oviduct hyperstimulated by progesterone

Quail oviduct development is controlled by sex steroid hormones. Estrogen (E) induce cell proliferation, formation of tubular glands by epithelial cell evagination and cell differentiation. Progesterone (P) strongly increases the secretory process in E-treated quails, but inhibits cell proliferation, cell evagination and differentiation of ciliated cells. The balance between E and P is critical for harmonious development of the oviduct. After 6 daily injections of two doses of estradiol benzoate (10 or 20 micrograms/d) and high doses of P (4 mg/d), tubular gland formation by epithelial cell evagination was inhibited, while epithelial cell proliferation occurred, as shown by the height of the villi and the increase in DNA. Secretory processes were strongly stimulated. Ovalbumin, a tubular gland cell marker and avidin, a mucous cell marker, were localized by immunofluorescence and immunogold labeling. Ovalbumin was localized only in the rudimentary tubular glands, whereas avidin was dispersed throughout the secretory cells. High doses of progesterone inhibited tubular gland cell proliferation, disturbed the distribution of avidin and inhibited differentiation of ciliated cells. Ovalbumin synthesis occurred only in epithelial cells which were evaginated despite the hyperstimulation. Ovalbumin gene expression appeared highly dependent upon the cell position.     

A significant lag in the induction of ovalbumin messenger RNA by steroid hormones: a receptor translocation hypothesis.

Although ovalbumin and conalbumin mRNA accumulate in the same tubular gland cells of the chick oviduct in response to estrogen or progesterone treatment, the kinetics of induction are markedly different. Conalbumin mRNA begins to accumulate within 30 min after estrogen administration, whereas there is a lag of approximately 3 hr before ovalbumin mRNA begins to accumulate, as measured by three independent assays. The kinetics of estrogen-receptor binding to chromatin indicate that these sites are saturated within 15 min of estrogen administration to the chicks, demonstrating that the lag is not due to slow uptake of the steroid. Suboptimal doses of estrogen produce the same lag, but the resultant rate of ovalbumin mRNA accumulation is lower than with an optimal dose. Partial induction of ovalbumin mRNA by a low dose of estrogen does not shorten the lag with an optimal dose. With progesteone, there is a lag of about 2 hr before either ovalbumin or conalbumin mRNA begins to accumulate. Treatment of chicks with hydroxyurea shortens the lag for ovalbumin induction with either hormone. Inhibition of protein synthesis with emetine does not prevent the accumulation of either ovalbumin or conalbumin mRNA. With cycloheximide, however, ovalbumin mRNA accumulation can be prevented. The existence of a lag suggests that there are intermediate steps between the binding of steroid receptors to chromatin and the induction of ovalbumin mRNA. There are basically two models to explain these delays in response: one involving the accumulation of an essential intermediate, and the other involving a rate-limiting translocation of steroid receptors from initial nonproductive chromatin-binding sites to productive sites. Several aspects of the kinetics of ovalbumin mRNA induction are more consistent with the latter model.     

The induction of ovalbumin and conalbumin mRNA by estrogen and progesterone in chick oviduct explant cultures

Estrogen pretreated chick oviduct tissue can be restimulated in vitro by physiological concentrations of estrogen and progesterone. The rates of synthesis of the major egg white proteins, ovalbumin and conalbumin, as well as the cellular levels of their respective mRNAs, increase after characteristic lag periods; this confirms previously reported results in vivo and demonstrates that both the lag phenomena and the mRNA induction are a function of the direct interaction of steroids with oviduct cells.The antagonistic action of progesterone on an estrogen-mediated induction of conalbumin mRNA also occurs in vitro, and the kinetics of this response are examined. Progesterone terminates the estradiol-induced accumulation of conalbumin mRNA within 30 min after addition to the medium; progesterone alone or in combination with estrogen, however, is capable of inducing conalbumin mRNA after a 4 hr lag period. The temporary nature of this antagonism and the fact that it does not occur with ovalbumin induction indicate the complexity of the oviduct's response to steroids.The role of protein synthesis in the induction of both ovalbumin and conalbumin was examined by including protein synthesis inhibitors in the culture medium. Puromycin, cycloheximide, emetine, pactamycin and high salt all block the induction of both ovalbumin and conalbumin mRNA when added together with either estrogen or progesterone. The effect of puromycin is reversible. After the drug is removed from the medium, the mRNA accumulation begins with the same characteristic lag period seen when no inhibitors are added. When given 2 hr after estrogen, puromycin stops the accumulation of conalbumin mRNA within 30 min, whereas cycloheximide and emetine allow the mRNA to accumulate for another 2 hr before causing complete inhibition. There is no effect of protein synthesis inhibitors on the number of estrogen receptors localized in the nucleus. The data suggest a direct link between protein synthesis and the steroid-induced accumulation of specific mRNAs in this system.     

Opposite effects of glucocorticoid on estrogen-induced growth and differentiation of quail oviduct: demonstration by sequential treatments

Control of the development and functions of avian oviduct is monitored by four classes of steroid hormones, including glucocorticoids. The effects of dexamethasone (DEX), a synthetic glucocorticoid, were studied via sequential treatments with estradiol benzoate, paying special attention to changes in estrogenic oviduct responses involving DNA synthesis and cell proliferation, ovalbumin accumulation and cell differentiation. DEX exerted an antagonistic effect upon estrogen stimulation when administered separately before or after estradiol benzoate (EB). Given before EB, DEX was more strongly antagonistic for DNA synthesis than when given simultaneously with EB. Administered after EB, DEX reversed EB-induced cell proliferation: the DNA content declined and the oviduct regressed. In the same way, protein and ovalbumin synthesis was inhibited and delayed by first intervention of DEX, and accelerated catabolism of ovalbumin and proteins was observed when DEX followed EB. DEX, which was ineffective alone, but synergistic on ovalbumin synthesis when given concomitantly with EB, prevented or dissipated the estrogenic effects, cell proliferation and secretory process when administered in sequential treatments.     

Magnum morphogenesis during the natural development of the quail oviduct: analysis of egg white proteins and progesterone receptor concentration

The histological development of the quail oviduct and the changes in concentrations of progesterone receptor, ovalbumin, conalbumin, ovomucoid and ovoglycocomponents are analyzed during the period spanning 7-35 days of age. The initiation of luminal epithelial cell proliferation is the first event of magnum growth. The epithelial cells begin to evaginate into subepithelial stroma and form tubular glands. Meanwhile, luminal epithelium starts cellular pleomorphism through ciliogenesis. No egg white proteins are detectable in the developing glands; at the same time, the concentration of the progesterone receptor increases from about 5500 sites/cell to 30,300 sites/cell. Tubular gland cells then begin to synthetize and accumulate egg white proteins, mucous cells differentiate in the luminal epithelium, and the cell proliferation decreases and finally stops. Compared with earlier studies dealing with the blood levels of estrogen and progesterone in developing quails during the same period, and the cellular changes induced in the oviducts of ovariectomized and ovariectomized-hypophysectomized quail by exogenous steroids, these results distinguish between the cellular responses that are physiologically controlled by estradiol and other responses that have multihormonal regulation.     

Effects of serial hormone treatments on egg white protein synthesis. Further evidence of translational regulation

The administration of either progesterone or estrogen to withdrawn chicks several hours after a first dose of estrogen affected ovalbumin synthesis differently than its mRNA levels [S. S. Seaver (1981) J. steroid Biochem. 14, 949-957]. This suggested that the hormones were regulating the translation of ovalbumin directly. In this paper we report that serial hormone treatments also affect the rates of synthesis of two other egg white proteins, conalbumin and ovomucoid. When progesterone was administered 4 h after estrogen, conalbumin synthesis decreased. When either progesterone or a second dose of estrogen was administered 12 h after the first dose of estrogen, conalbumin synthesis increased. Serial hormone treatments did not always affect all three proteins similarly. At later times, administering progesterone after estrogen decreased ovomucoid synthesis but did not affect conalbumin or ovalbumin synthesis. To determine if the serial hormone treatments affect egg white protein mRNA's in a similar way, changes in ovalbumin and conalbumin mRNA levels were quantified in a rabbit reticulocyte cell-free translation system and were compared to changes in ovalbumin and conalbumin synthesis as measured in chick oviduct tissue minces. When serial hormone treatments were 12 h apart, ovalbumin and conalbumin synthesis was 50-300% higher than that predicted by the changes in ovalbumin or conalbumin mRNA levels. This is further evidence that translation of both conalbumin mRNA and ovalbumin mRNA is directly regulated by steroid hormones.     

The chicken ovalbumin promoter is under negative control which is relieved by steroid hormones.

Steroid hormone regulation of activity of the chicken ovalbumin promoter was studied by microinjection of chimeric genes into the nuclei of primary cultured oviduct tubular gland cells. The chimeric genes contained increasing lengths of ovalbumin gene 5'-flanking sequences fused to the sequence coding for the SV40 T-antigen. Promoter activity was estimated by monitoring synthesis of T-antigen. The activity of the ovalbumin promoter is cell-specifically repressed in these oviduct cells and the repression is relieved upon addition of steroid hormones. The -132 to -425 region of the ovalbumin promoter which is responsible for this negative regulation behaves as an independent functional unit containing the regulatory elements necessary for both repression (in the presence of steroid hormone antagonists) and induced derepression (in the presence of steroid hormones) of linked heterologous promoters.